US2303076A - Treatment of hydrocarbons - Google Patents

Description

Patented Nov. 24, 1942 'ritmi'rivrnm'r` oF mRooARnoNs Per x. Freuen, Westfield, N. J., assigner te stendard Oil'Development Company, a corporation of Delaware Application May18, 1938, Serial No. 208,545

1 Claim. (Cl. 196-49) The inventionl relates te the treatment of hydrocarbons in the presence of a catalystand more particularly to the cracking and reforming ofv petroleum oils and derivatives of substances containing tar, such as coal and lignite.

In the catalytic treatment of hydrocarbon vapors, carbonaceous material is deposited in the` catalyst, necessitating periodic regeneration by burning out the carbondeposit.

As is well known, catalytic reforming and catalytic cracking processes are endothermic rather than exothermic in thatr heat is consumed in the process, with a resulting decrease in temperature. In order to maintain thel temperature ata relatively constant level throughout the cracking zone, it is necessary to supply heat to the vapors during their passage through to the reaction zone. It is extremely dimcult to carry out such an operation on a commercial scale because of the practical objections to supplying heat at a high temperature level, particularly when this temperature level is to be maintained constant within narrow limits.

In view of this, it has been proposed to pre,- heat the oil vaporspassing to the reaction zone to a temperature sufficient to eect the desired conversion without the application of additional heat to the products passing through the reaction zone. This requires heating the oil vapors initially to a temperature. suiliciently above the desired reaction temperature to compensate for the drop in temperature through the reaction zone. When operating in this manner, the vapors to be cracked when rst coming in contact with fresh catalyst tend to become over-cracked resulting in the formation of excessive gas losses.

One of the objects of this invention is to provide a method which will permit supplying sufficient -heat to the fresh vapors to effect the desired amount of cracking and which, at the same time will avoid undesirable overcracking in the Y initial stage of the reaction zone.

In accordance with my invention, the feed stock to be cracked Vis initially heated to a temperature sufficient to accomplish the desired amount of cracking without the addition of further heat during the reaction period. The fresh highly heated vapors are then passed through a catalyst zone or zone containing catalyst of progressively increasing activity so that the highly heated vapors contact with the less active catalyst .and overcracking is avoided. As the temperature becomes lower, the activity of the catalyst increases so thatthroughout the cracking period substanwords, as the temperature o1' the vapors drops of! due to the endothermic nature of the reaction, the activity of the catalyst is increased so that a relatively uniform rate of. conversion is accomplished throughout the cracking zone.

My invention further comprehends a novelarrangement of apparatus. for accomplishing 'the' desired objectives. It will be understood, however, that the method is not restrictedto the par-- ticular apparatus illustrated nor is the apparatus limited to carrying out the specific method dis-y closed. l Y

Other objects and advantages will appear as the description proceeds. Y

In the accompanyingV drawing, I have illustratedr I diagrammatically an arrangement of apparatus suitable for carrying out my improved method. It will be understood that the method is adapted for use with any number of reaction chambers although I consider that the employment of four chambers gives very satisfactoryV temperature control, three of the chambers being on stream while the fourth is onregenerationJ ,Y

AIhave lshown in the drawing four reaction chambers I, 2,' 3, and 4 arranged in series. vThese maybe of any conventional construction sl'iitable'-V for use in the cracking or reforming of hydrocarbons. In the layout chosen for the purpose lof illustration, a double manifold extends over the' top of the chambers, and they are connected tol gether at the bottom by another double manifold so arranged as to permit periodic regeneration of the catalyst in the several chambers. f

The gaseous hydrocarbon feed stock is intr duced intov the system through the feedV line 8 and Vthe reaction products are withdrawn through the line 1. For convenience ci reference in describing the flow of the hydrocarbon vapors through the several reactors and connecting headers or manifolds,` the connecting portions of the headers have been numbered consecutively4 from 8 to I8, inclusive. The dotted lines I 9 and 20represent manifolds and connections for regenerattially uniform conversion is effected. In other'55 ing gas and it will be understood that these manifolds and connectionsare provided with valves so arranged as to permit regeneration of the catalyst in each reaction chamber in rotation.

I shall now describe the operation of my improved method as applied to the cracking of petroleum oil. Consider first that the chamber I has been removed from the cracking cycle for regeneration, that the reaction chamber I contains the oldest useable catalyst (i. e., the catalyst with the largest deposit of carbonaceous material),

that reaction chamber 2 contains a lesser amount I of carbonaceous deposit and reaction chamber 3 either a new bed of catalyst or a freshly regenerated catalyst. The valves in the headers and connecting pipes are set in the proper positions to produce flow in the cycle indicated by the following sequence: 6, 1, 13, 2, l1, 3, 18, '7. After ilow in accordance with this cycle has continued up to the point where the catalyst in chamber I is to be regenerated, the valves v and the valves in the regenerator connections are set so as to produce flow of regenerating gases through the chamber l and flow of the hydrocarbon vapors in accordance with the following cycle: 6, 10, 2, 14, 3, 12, 4, 7.

Similarly when the catalyst in chamber I has been regenerated and that in chamber 2 is ready for regeneration, the latter is removed from the cracking cycle and placed on regeneration, the valves being set to provide flow of the hydrocarbon vapors in accordance with the cycle 6, 10, 1l, 3, 15, 4, 9, 8, 1, 16, 17, 18, 7. Finally, when reaction chamber 3 is to be placed on regeneration, the valves are set to produce flow in accordance with the cycle 6, 10, 11, 12, 4, 15, 14, 13, 1, 8, 2, 17, 18, 7.

The invention is not predicated upon any particular arrangement of apparatus but rather upon the novel steps of the method which comprises bringing the vaporized hydrocarbons ilrst into contact with a catalyst having a substantial carbon deposit in association therewith, and bringing the products of this reaction into contact with a catalyst having an appreciably lower carbon deposit per unit volume. The arrangement of apparatus which I have described is adapted to the practice of these steps and also the practice of a method comprising the steps of bringing the vaporized hydrocarbons consecutively into contact with separate catalytic masses having successively decreasing amounts of carbon in association therewith, each of these successive contacts being effected at a lowertemperature than the tionation or separation of any of its fractions.

In this way, it is possible to take advantage oi.' the endothermic nature of the reaction in order to adjust or assist in adjusting the temperature at which a succeeding cracking step is to be performed. This is a decided advantage when employing successive-beds of catalyst adapted to eilicient operation at decreasing temperatures.

In practicing the method which I have described, the temperature in the first reaction chamber is the highest and results in substantial conversion while avoiding excessive gas formation. The last chamber containing the most newly regenerated catalyst is operated at vthe lowest temperature, which also decreases gas formation which proceeds at a lower rate as the temperature is decreased. The result is a maximum conversion for the complete cycle. As the conversion in the first chamber drops to an extent that it no longer becomes profitable to operate it, the valves are then set so as to remove it from the system and it is subjected to regeneration, the feed being diverted to the second chamber and continued through the remaining chambers up to and including the one containing the fresh catalyst which has just been removed from the regenerating cycle and returned to the cracking cycle.

When my method is to be used in the cracking of gas oils or heavier, the temperatures in the reaction chambers ordinarily will vary from 900 t 950 F.,'in,the rstchamber of the series, to about 800 to 8510"15'3inv the last chamber. It should be understood'that reference to the first chamber of the series means the one which contains the catalyst with the largest amount of carbon deposit andfreference to the last chamber means the one-'which contains the lowest amount of carbon deposit,lirrespective of the particular arrangement of .the chambers. I prefer to maintain the temperature in the ilrst chamber at between 900 to 950 F., with successively decreasing temperatures inthe succeeding chambers, bringing the temperature in the last chamber to about 800 to 850 F. As previously pointed out. the maintenance of the temperatures in succeeding stages of the cracking cycles is assisted to a substantial degree by the endothermic nature of the reaction which causes a reduction in the temperature as is desired in order to obtain optimum conditions for conversion.

In applying my method to the catalytic reforming of naphtha, the temperatures will be somewhat higher than in the catalytic cracking operation'. For example, the temperature in the first chamber of the series may be maintained at 1000 to 1050 F., and that in the last chamberof the series at about 850 to 900 F. with the temperature or temperatures in the intermediate stage or stages lying between these values so that the system presentsaseries of reactions at successively decreasing temperatures. Substantially all of the products of each stage are carried into the succeeding stage.

The feed stock delivered to the system through the line 8 may be preheated in any suitable manner known to the art, as by means of thel usual pipe still. The reaction products drawn olf from the last reaction chamber of the series through the line 'l may be subjected to further processing in accordance with well-known practice as, for example, by fractionation and separation. These steps form no part of the present invention which is concerned merely with the stages of cracking, reforming, or other catalytic treatment.

This method makes it possible not only to operate successive cracking stages at temperatures approaching optimum conditions with respect to conversion in accordance with the condition of the catalyst, but also to take advantage of the endothermic nature of the reaction to assist in bringing the temperature to the desired value for each succeeding stage. These results are accompllshedwithout the necessity of providing a large amount of equipment. These and similar advantages of the method disclosed herein may be attained in substantial degree withy arrangements of apparatus quite different than that described for the purpose of illustration. The terms and expressions which are employed are used as terms of description and not of limitation, and there is no intention of excluding any equivalents oi' the invention set forth, or of portions thereof.

I claim:

In a process for the catalytic cracking of hydrocarbon oils wherein a bank of catalytic converters containing a mass of cracking catalyst is provided which is subjected to periodic regeneration in situ to remove carbonaceous deposits formed thereon during the cracking treatment and wherein the cracking and regeneration periods in the individual converters are arranged in staggered relation one to another in such manner that when one converter is starting a cracking period another conversar-*1s sz s ofltns mung period while snother ls undersoins retener-ation; i the improvement which. comprises*y lnltdwnllyV passing the oil tobe ycracked vthrough the oonl v'erter in the lster stages o! the crackingy period snd thereafter pssslng all vapor produotsirom the last-named converter through s conyerterln.

the earlier stages of perlodwherehy fr n shorter

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